Abstract: System and method for providing power to circuitry while avoiding a large transient current. A preferred embodiment comprises a distributed switch (such as switch arrangement 400) with a plurality of switches (such as switch 405) coupling a power supply to the circuitry. Each switch is individually controlled by a control signal and is turned on sequentially. Also coupled to each switch is a pre-driver circuit (such as pre-driver circuit 410). The pre-driver circuit comprises a potential adjust circuit (such as potential adjust circuit 505) that rapidly adjusts a voltage potential at the switch and a rate adjust circuit (such as the rate adjust circuit 520) that accelerates the power ramp-up across the switch once transient currents are no longer a concern. Adjusting the voltage potential so that the switch operates in a saturation mode increases an effective capacitance across the switch and thereby retarding the power ramp-up across the switch.

Abstract: Each of computing units on a semiconductor integrated circuit includes a first signal output unit that outputs a first status signal indicating a state of a input/output control unit with regard to an access to a storage unit, a second signal output unit that outputs a second status signal indicating a state of a process control unit with regard to an access to a processing unit, and a power control unit that control ON and OFF of power of the storage unit and the processing unit based on states of the first status signal and the second status signal.

Abstract: In one embodiment, a leakage reduction circuit is provided that includes: a virtual power supply node; a first PMOS transistor coupled between the virtual power supply node and a power supply node; a second PMOS transistor having a source coupled to the power supply node; and a native NMOS transistor coupled between a drain of the second PMOS transistor and the virtual power supply node, the native NMOS transistor having a gate driven by the power supply node.

Abstract: A semiconductor integrated circuit includes: a circuit block having a first power supply line to which one of a power supply voltage and a reference voltage is applied, an internal voltage line, and a circuit cell connected between the first power supply line and the internal voltage line; and a plurality of switch cells each including two voltage cell lines each connected electrically to the internal voltage line, two power cell lines each connected electrically to a second power supply line to which another of the power supply voltage and the reference voltage is applied, a control cell line electrically connected to a switch control line, and a transistor electrically connected between the internal voltage line and the second power supply line.

Abstract: A system (10,90), apparatus (12,30,40,50,60,70) and method (100) is disclosed for detecting excess current leakage between drain/source of a metal oxide semiconductor (MOS) transistor (36,46) within a complementary MOS (CMOS) environment. A load control (32,42) is arranged as a compliment to the MOS transistor. A comparator (34,44) is electrically connected to the load control and the MOS transistor, and produces an output signal representative of the detection of a current leakage exceeding a threshold. In response to the received output signal indicating an excess current leakage, system voltage/frequency may be adjusted to prevent damage to the CMOS environment.

Abstract: In one example embodiment, a speed circuit path includes inverter chains that are controllable to operate in a slower, low sub-threshold leakage current mode or a faster, higher sub-threshold leakage current mode depending on an operating mode of the semiconductor device. A non-speed circuit path includes inverter chains that operate to reduce sub-threshold leakage current regardless of an operating mode of the semiconductor device.

Abstract: In one embodiment, a circuit includes a first row of circuit blocks that are each connected to a supply directly and to ground via a first sleep transistor. A connection between the first circuit block and the first sleep transistor is a virtual ground node. The circuit includes a second row of circuit blocks that are each connected to ground directly and to the supply via a second sleep transistor. A connection between the second circuit block and the second sleep transistor is a virtual supply node. The circuit includes a transmission gate (TG) or pass transistor connecting the virtual ground nodes to the virtual supply nodes to enable charge recycling between circuit blocks in the first row and circuit blocks in the second row during transitions by the circuit from active mode to sleep mode, from sleep mode to active mode, or both.

Abstract: An electronic circuit includes a receiver circuit (BSP) operable to perform coherent summations having a coherent summations time interval, and a power control circuit (2130) coupled to said receiver circuit (BSP) and operable to impress a power controlling duty cycle (TON, TOFF) on the receiver circuit (BSP) inside the coherent summations time interval. Other circuits, devices, systems, methods of operation and processes of manufacture are also disclosed.

Abstract: The present invention relates to a semiconductor integrated-circuit device capable of seamlessly switching a power source obtained by rectifying a carrier wave and an external power source. The semiconductor integrated-circuit device having a non-contact card function and a non-contact reader/writer function includes a rectifier 131 for rectifying a received carrier wave, a serial regulator 132for obtaining a predetermined voltage from an output voltage of the rectifier 131, and a power-supply control circuit 138 for turning on/off the voltage from a battery 160. In a case where the output voltage of the battery 160 is equal to or higher than a predetermined voltage, the power-supply control circuit 138 selects the voltage of the battery 160 as power required for operation of an IC 300 when a reader/writer mode signal or a card mode signal is received.

Abstract: A digital photo frame having power saving functions includes a display panel, a power generation unit for switching a system power according to a power control signal, a user detection unit installed on the display panel for detecting whether a user exists within a specific range to generate a user detection signal, a central processing unit for adjusting backlight intensity of the display panel when the system power is provided by the power generation unit according to the user detection signal and for generating a power switch-off signal when the backlight intensity of the display panel is turned off according to the user detection signal, and a power control unit for generating the power control signal to switch off the system power when the backlight intensity of the display panel is adjusted to be switched off according to the power switch-off signal.

Abstract: A controlling circuit for automatically adjusting clock frequency of a CPU is provided. The controlling circuit includes: a current sensing circuit for converting a current signal of the CPU to a voltage signal; a voltage amplifying circuit for amplifying the voltage signal; a multi-stage switching circuit for converting the amplified voltage signal to switched signals; and a priority decoding circuit decoding the switched signals, the decoded switched signals being input to a clock generator of the CPU, and thereby adjusting the clock frequency of the CPU to fit different load on the CPU.

Abstract: The available battery power on autonomously powered mobile electronic devices, in particular smartcards, is very small but requires a very long shelf life. Thus, even very small rest currents are a big power issue. The invention discloses a power save circuit and method, where a single power switch, e.g. a FET or a MEM switch, can be used to detach the power supply (?) from the whole system and allow the lowest current possible. Further, a combination with a double action button and integration of the power switch provides a solution with a minimum number of components and interconnects. An option for “system wake-up at any button” enables additional power saving during use, without inconvenience to the user.

Abstract: In one embodiment, a circuit includes a first circuit block connected to ground via a first sleep transistor, a first virtual ground node between the first circuit block and the first sleep transistor, a second circuit block connected to ground via a second sleep transistor, a second virtual ground node between the second circuit block and the second sleep transistor, and a transmission gate (TG) or a pass transistor connecting the first virtual ground node to the second virtual ground node to enable charge recycling between the first circuit block and the second circuit block during transitions by the first circuit block from active mode to sleep mode and the second circuit block from sleep mode to active mode or vice versa.

Abstract: A semiconductor device including an AND-NOR composite gate of which AND unit is supplied with input signals IN and VDD and NOR unit is supplied with an inverted signal EB of an enable signal E, and an AND-NOR composite gate of which AND unit is supplied with an input signal INB and an enable signal E and NOR unit is supplied with VSS. These gates are inserted into a path to which the input signals IN and INB are supplied. Thereby, a symmetric property of a complimentary signal can be retained. Further, outputs of the AND-NOR composite gates are fixed irrespective of a logical level of the enable signal E. Thus, a sub-threshold current also is inhibited.

Abstract: A receiver circuit includes: a current/voltage conversion circuit which performs a current/voltage conversion based on current which flows through the differential signal lines and outputs voltage signals; a comparator which compares the voltage signals and outputs an output signal; a power-down detection circuit which, when the transmitter circuit transmits a power-down command by current-driving the differential signal lines in a normal transfer mode, detects the transmitted power-down command based on a comparison result from the comparator; and a power-down setting circuit which sets at least one of the current/voltage conversion circuit and the comparator to a power-down mode when the power-down command is detected.

Abstract: A system includes a first semiconductor device, a second semiconductor device, and an external crystal oscillator. The first semiconductor device includes a source voltage output and an external pin input. The first semiconductor device includes a direct current-to-direct current (DC-DC) converter circuit that provides the source voltage output. The second semiconductor device includes a source voltage input that is coupled to the source voltage output of the first semiconductor device and includes a clock signal output. The external crystal oscillator is coupled via an input of the second semiconductor device to a first oscillator clock generation circuit.

Abstract: A power-down mode control apparatus includes an internal power-down control block configured to receive a locking completion signal and to generate an internal power-down signal, which is toggled for a predetermined time; a noise check block configured to check occurrence/non-occurrence of noise on the basis of a phase detection signal and to generate a plurality of power-down selection signals in response to the locking completion signal and the internal power-down signal; and a power-down enter control block configured to generate a plurality of power-down enter signals, which instruct individual circuits to enter a power-down mode in response to a reference clock signal, the plurality of power-down selection signals, a power-down mode signal, and the internal power-down signal.

Abstract: A power saving charger comprises a switch circuit having an input end connected to an AC current source for turning on or turn off AC current; a switch driving circuit having an output end connected to the switch circuit for outputting signals to turn on or turn off the AC current of the switch circuit; a charging circuit connected to the output end of the switch circuit for converting AC current to DC current so as to charge to a battery of an external load; and a charge detection circuit connected to a charge output end of the charging circuit and a signal output end of the charging circuit for detection the completeness of the charge and detection of the existence of the load; and a signal output end of the charge detection circuit being connected to an signal input end of the switch driving circuit.

Abstract: An energy-saving circuit and method using charge equalization across complementary nodes reduces power consumption in memory circuits and other circuits such as wide multiplexers having complementary high-capacitance nodes. A change detection circuit detects a state change to be applied to the bitlines, and generates a pulse if a state change is to be applied. A pass gate connected between the nodes is activated in response to the pulse to equalize the charge on the bitlines. The driver circuit enable inputs are also delayed, so that the bitlines are not driven until after the charge has been equalized and the pass gate disabled. In one embodiment, the driver circuits are only enabled momentarily by a pulsed output of the change detector and keeper circuits are employed to retain the bitlines in their asserted states.

Abstract: A timing control circuit with a power-saving function includes a receiving circuit, a processor, and a first switch. The receiving circuit receives a first set of differential signals for generating a set of command signals. The processor is coupled to the receiving circuit and generates a first control signal according to the set of command signals. The switch is coupled between the receiving circuit and the processor for selectively decoupling the receiving circuit from a first power supply according to the first control signal.

Abstract: A multi-threshold CMOS system and method controls a state of respective blocks individually. Each block includes a logic circuit having a logic transistor and a control transistor connected between the logic circuit and a power line connected to one of a ground and a power source. The control transistor has a higher threshold than the logic transistor. The blocks are controlled by generating an individual block ON/OFF signal for each block, generating an individual control signal in response to the individual block ON/OFF signal, supplying the individual control signal to the control transistor and controlling voltage supply to the logic circuit within each block in accordance with the individual control signal.

Abstract: An integrated circuit device comprises an internal pull up current source Ipup and a pull up resistor Rpup connected in parallel between a voltage supply pin Vs and an output node OUT. A standby switch SBY is connected in series with the pull up resistor Rpup. The standby switch SBY is controlled by a standby detect means SBY Detect, which is also connected to the output node OUT. If it is desired to switch the device to standby mode, the output node OUT is externally drawn to ground by microprocessor 200. The circuit stays in the standby mode as long as the OUT is drawn to ground. In order to save current during standby mode, the SBY Detect is operable to disconnect the pull-up resistance Rpup by means of switch SBY. As the pull-up resistance Rpup is disconnected during the standby mode, the current source Ipup supplies a minimal current to OUT. This ensures that the circuit can always leave an undesired standby mode rapidly.

Abstract: A semiconductor integrated circuit is provided including a plurality of circuit blocks and adapted to cut off the supply of power source voltage to any one of the circuit blocks. The integrated circuit includes an interblock interface circuit provided on a signal path between an elected circuit block and a branch point at which the signal path branches into different branch paths so as to connect to other circuit blocks. The interblock interface circuit includes a signal gate for preventing signal transmission from the elected circuit block to the other circuit blocks, and includes a storage unit for storing a signal right before the power cut-off.

Abstract: A circuit is disclosed for retaining a signal value during a sleep mode while a portion of said circuit is powered down comprising: a clock signal input operable to receive a clock signal; at least one latch clocked by said clock signal; a data input, a data output and a forward data path therebetween, wherein a signal value is operable to be received at said data input, is clocked through said at least one latch and passes to said data output along said forward data path; at least one of said at least one latch comprises a retention latch operable to retain a signal value during said sleep mode, said retention latch not being located on said forward data path; and a tristateable device, said tristateable device being arranged between said forward data path and said retention latch and being operable to selectively isolate said retention latch from said forward data path in response to receipt of a first sleep signal; wherein in response to receipt of a second sleep signal, said second sleep signal being rece

Abstract: An exemplary power supply circuit configured for supply power for a load includes: a main power supply configured for converting received voltages into required direct current voltages; a microprocessor configured for providing control signals; a stand-by control circuit configured for controlling the main power supply; an energy storage circuit configured for supplying the stand-by control circuit. When the load stops operating, the microprocessor outputs a control signal to the stand-by control circuit, the stand-by control circuit outputs a corresponding control signal to turn off the main power supply. In response to when the load starts operating, the stand-by control circuit outputs a corresponding control signal to turn on the main power supply, and the main power supply charges the energy storage circuit.

Abstract: An authentication device or other type of low-power hand-held device comprises a processor, an external button alternately configurable in an unpressed state and a pressed state, and current drain mitigation circuitry coupled to the external button and a corresponding input of the processor. The current drain mitigation circuitry is configured to connect the input of the processor to a first potential when the external button is in the unpressed state and to connect the input of the processor to a second potential different than the first potential when the external button is in the pressed state, thereby limiting current drain arising from the external button being stuck in the pressed state.

Abstract: A power management circuit is provided for controlling power dissipation in at least one combinational logic circuit. The power management circuit includes a detector operative to receive at least a first input signal to the combinational logic circuit and to detect a transition of the first input signal between a first logic state and a second logic state. The detector generates a control signal indicative of whether or not a transition of the first input signal has occurred.

Abstract: In related arts, a body voltage needs to be controlled by separately detecting external environment such as temperature. In the related art, variation such as a process parameter for each individual product has not been considered. A semiconductor integrated circuit according to the present invention includes a comparator comparing a leak current of a first conductive type transistor with a leak current of a second conductive type transistor to output a comparing result, and a conduction control signal generator outputting a signal determining a conduction state of the first conductive type transistor and a conduction state of the second conductive type transistor in a power saving control target circuit in a power saving mode based on the comparing result.

Abstract: According to one embodiment, a semiconductor device includes an internal circuit which is driven by a power supply voltage and is set in one of a first state and a second state in which an amount of current consumed by the internal circuit is greater than in the first state, and a wait control module. The wait control module detects that a state of the internal circuit has transitioned from the first state to the second state, and executes a wait control process of outputting an operation start instruction signal to the internal circuit after passing of a predetermined wait time from the detection of the transition of the state of the internal circuit from the first start to the second state.

Abstract: A sensor apparatus is disclosed. A sense circuit is provided to convert inputted physical quantity to electrical signal. An amplifier amplifies an analog signal outputted from the sense circuit. An AID converter converts the output signal of the amplifier to digital data. A sensing interval setup unit sets a sensing interval for the sense circuit. A power supply unit supplies electric power to the sense circuit, the amplifier and the A/D converter. The amplifier and the A/D converter constitute an analog signal processing unit. A power supply control unit is provided to control the power supply unit. A storage unit stores the digital data outputted from the A/D converter every sensing interval of the sensing interval. A data value change judgment unit changes the setup of the sensing interval by the sensing interval setup unit.

Abstract: A device for adaptively controlling a voltage supplied to circuitry in substantially close proximity to the device, comprising a processing module, a first tracking element coupled to the processing module and producing a first value indicative of a first estimated speed associated with the circuitry, and a second tracking element coupled to the processing module and producing a second value indicative of a second estimated speed associated with the circuitry. The processing module compares each of the first and second values to a target value and causes a voltage output to be adjusted based on said comparison.

Abstract: A power managing apparatus is utilized to control a first supply voltage, a second supply voltage, and a substrate voltage of a digital circuit. The power managing apparatus includes a voltage generating device, for generating a first reference voltage and a second reference voltage; and a voltage switching device, coupled to the voltage generating device, for adjusting the first supply voltage, the second supply voltage, and the substrate voltage. When the digital circuit operates in a first operating mode, the voltage switching device outputs the second reference voltage to be the first supply voltage and the substrate voltage; and when the digital circuit operates in a second operating mode, the voltage switching device outputs the first reference voltage to be the first supply voltage, and outputs the second reference voltage to be the second supply voltage.

Abstract: A method includes parsing a design of the integrated circuit to define cells in automatic power gating power domains, automatically creating an automatic power gating power domain netlist from the parsed design of the integrated circuit, and placing and routing the automatic power gating power domain netlist to produce a layout for the integrated circuit. The parsing partitions a high-level power domain of the integrated circuit into one or more automatic power gating power domains. The automatic power gating power domains have substantially zero-cycle power up times, thereby enabling transparent operation. Furthermore, the automatic power gating power domains may be automatically inserted into designs of integrated circuits, thereby relieving integrated circuit designers of the task of inserting power domains and associated hardware and software.

Abstract: A charge recycling power gate and corresponding method are provided for using a charge sharing effect between a capacitive load of a functional unit and a parasitic capacitance of a charge recycling means to turn on a switching means between a virtual ground and a ground, the charge recycling power gate including a first transistor, a virtual ground in signal communication with a first terminal of the first transistor, a ground in signal communication with a second terminal of the first transistor, a capacitor having a first terminal in signal communication with a third terminal of the first transistor and a second terminal in signal communication with the ground, and a second transistor having a first terminal in signal communication with the virtual ground and a second terminal in signal communication with the third terminal of the first transistor.

Abstract: Disclosed herein is a semiconductor integrated circuit including, a circuit section, a first voltage line, a second voltage line, a third voltage line, a switch section, and a control section.

Abstract: An electronic circuit has a signal conductor (11), a power supply reference conductor (10) connected by a switching circuit. The switching circuit contains a PMOS transistor (17) and an NMOS transistor realized on a common substrate (100). The NMOS transistor (17) has a source coupled to the power supply reference conductor (10). The NMOS transistor (18) has a source coupled to the drain of the PMOS transistor (17), and a drain coupled to the signal conductor (11). A control circuit (13, 14, 15, 16) switches between an “on” state and an “off” state, in which the control circuit (13, 14, 15, 16) controls the gate source voltages of the first and second MOS transistor (17, 18) to make channels of these MOS transistors (17, 18) conductive and not to make the channels of these first and second transistors (17, 18) conductive respectively. Preferably a complementary switching circuit is also provided.

Abstract: Methods and arrangements to configure power management systems for integrated circuits are provided herein. A group of IC components that are functionally distinct or have mutually exclusive and/or quasi-mutually exclusive, (ME/QME) operating patterns (i.e. alternate or partially overlapping duty cycles) can be powered with a single power cell. An integrated circuit design tool can identified components in an integrated circuit design that have the ME/QME operating patterns. These cells can be collocated in close proximity to each other and power management system components can be placed in this area such that a multiple signal processing cells can share a single power line and a single power cell. Such a configuration can greatly reduce the size of a power management system for an integrated circuit.

Abstract: A circuit having a local power block for leakage reduction is disclosed. The circuit has a first portion and a second portion. The first portion is configured to operate at a substantially greater operating frequency than the operating frequency of the second portion. The second portion has a local power block configured to decouple the second portion if the second portion is inactive to reduce leakage current associated with the second portion without sacrificing performance of the first portion.

Abstract: A radio frequency power amplifier (RF PA) apparatus includes an RF PA and a waveform converter. The waveform converter is configured to receive a sinusoidal RF signal and generate a nonsinusoidal RF signal, which is used to drive an active device (e.g., a field effect transistor (FET) or bipolar junction transistor (BJT)) of the RF PA. The nonsinusoidal RF signal, which may comprise a square wave or a substantially-square wave signal, has signal characteristics that result in less leakage through the active device's input-output parasitic capacitance, compared to the leakage that would result if the sinusoidal RF signal was used to drive the active device. The leakage control methods and apparatus of the present invention may be advantageously employed in a variety of applications including, for example, RF polar transmitters.

Abstract: Disclosed herein is a semiconductor integrated circuit including a stoppable circuit unit configured to be alternately switched between a stopped state and an operating state; a first voltage line configured to apply a first voltage to the stoppable circuit unit when the stoppable circuit unit is in the operating state; a second voltage line configured to apply the first voltage to the stoppable circuit unit when the stoppable circuit unit is in a transient state of switching from the stopped state to the operating state; and a third voltage line configured to apply a second voltage to the stoppable circuit unit.

Abstract: A standby power supply system in an electronic device including a power-consuming circuit is provided. The standby power supply comprises a signal sensor, a standby power source, a switch circuit, a charge circuit and a power control unit. The signal sensor receives a system-on signal and generates a charging signal and a power-on signal according to the system-on signal. The standby power source provides a first voltage that the signal sensor needs in a standby status. The switch circuit receives the charging signal and then is conducted for a predetermined period. When the switch circuit is conducted and the charge circuit proceeds to charge to a predetermined voltage, the charge circuit turns on the power control unit to receive the power-on signal. The power control unit turns on the operation power supply according to the power-on signal, such that the operation power supply provides an operating voltage to the power-consuming circuit.

Abstract: In one embodiment, a method of leakage control for a memory having an array of memory cells arranged into a plurality of sub-arrays is provided wherein each sub-array has a sleep mode of operation controlled by a sleep signal in which stored data is lost, and wherein each sub-array asserts a local clock if the sub-array is addressed. The method includes the act of asserting a sleep signal while addressing a given one of the sub-arrays such that only the given one of the sub-arrays is placed into the sleep mode.

Abstract: The image sensing device interface unit attached to an image sensing device has dedicated means to detect a complete missing line and to perform clock gating of circuits for power management self-optimization. For each image frame, the time interval between start of line 1 and start of line 2 is computed and stored in a first register. The time interval between any other pair of two consecutive lines is also computed and stored in a second register. The stored values are compared, and if the value in the second register is greater than in the first register, a complete missing line has been detected and the gated clock used in said circuits is switched off for power saving. The interface unit can adapt to any type of sensor and does not require the help of any processor to perform the power saving function.

Abstract: A semiconductor device including first and second power lines, and first and second circuit blocks coupled between the power lines. A first switching element is inserted between the first circuit block and at least one of the power lines and a second switching element is inserted between the second circuit block and at least one of the power lines. The first switching element is rendered conductive to allow the first circuit block to receive the power voltage through the first and second power lines while the second switching element is rendered nonconductive to prevent the second circuit block from receiving the power voltage through the first and second power lines, so that a leakage current flowing through the second circuit is suppressed.

Abstract: An integrated circuit is provided comprising a first NMOS transistor; a first PMOS transistor; a second NMOS transistor; a second PMOS transistor; a first bias voltage node coupled to a first source/drain of the first NMOS transistor; a second bias voltage node coupled to a first source/drain of the second PMOS; a third bias voltage node coupled to a gate of the first PMOS transistor; a fourth bias voltage node coupled to a gate of the second NMOS transistor; a pull-up node coupling a second source/drain of the first NMOS transistor to a first source/drain of the first PMOS transistor; a pull-down node coupling a second source/drain of the second PMOS transistor to a first source/drain of the second NMOS transistor; an input node; a storage node coupling a second source/drain of the first PMOS transistor to a second source/drain of the second NMOS transistor; an output node; an input switch coupled to controllably communicate an input data value from the input node to a gate of the first NMOS transistor and t

Abstract: It is intended to provide a semiconductor integrated circuit device and adjustment method of the same semiconductor integrated circuit device, capable of adjusting an analog signal outputted from an incorporated analog signal generating section without outputting it outside as an analog value. An analog signal AOUT is outputted from an analog signal generating section 3 in which an adjustment signal AD is inputted. The analog signal AOUT is inputted to a judgment section 1, in which it is compared and judged with a predetermined value and then a judgment signal JG is outputted. The judgment signal JG acts on a predetermined signal storing section 4 as an internal signal and the adjustment signal AD is fetched into the predetermined signal storing section 4. Further, the judgment signal JG is outputted as digital signal through an external terminal T2 and an external tester device acquires the adjustment signal and stores the acquired adjustment signal in the predetermined signal storing section 4.

Abstract: An apparatus and method are provided for preventing a current leakage or direct current when a low voltage domain is powered down. Included is a voltage transition circuit connected between a low voltage domain and a high voltage domain. Such voltage transition circuit includes a circuit component for preventing a current leakage when the low voltage domain is powered down.

Abstract: This device has a first circuit including a first field effect transistor and a second circuit coupled to a source of the first electric field transistor. The second circuit applies a first source bias voltage, which does not reversely bias between a source and a body of the first field effect transistor, to the first field effect transistor during the operation mode of the first circuit, and applies a second source bias voltage, which reversely biases between the source and the body of the first field effect transistor, to the first field effect transistor during the standby mode of the first circuit. During the standby mode of the first circuit, the leakage current that flows through the first FET is reduced by means of the reverse bias effect produced by applying the second source bias voltage to the source of the first FET.

Abstract: A method and an apparatus powers down an analog integrated circuit. A power down circuit is electrically coupled to the analog circuit and is adapted to power down the analog circuit in response to receiving a power down signal. A node protection circuit is electrically coupled to the analog circuit and is adapted to provide a predetermined voltage potential to at least one predetermined node in the analog circuit in response to receiving the power down signal when a voltage potential at the at least one predetermined node is not determined by the power down circuit.

Abstract: Activation of an external sensor coupled to an electronic device will change the frequency of a low power oscillator in the electronic device that runs during a low power sleep mode of the electronic device. When a change in frequency of the low power oscillator is detected, the electronic device will wake-up from the low power sleep mode. In addition, when a change in frequency from an external frequency source is detected, the electronic device will wake-up from the low power sleep mode.